Sharra Grow Winterthur/University of Delaware Program in Art Conservation When New and Improved Becomes Outdated and Degraded: The Technical Study and Treatment of a 1964 Pop Art Painted Collage abstract

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C. Paper Elements

The presence of Ti in all the paper element samples analyzed suggested the presence of titanium dioxide in the paper, likely present as a whitening agent (Beazley 1991). The Ca detected in the brown paper sample was likely from calcium carbonate, which has been used as a filler and coating for papers in the United States since the 1920s (Beazley 1991). Al and Si are often present in magazine papers in the form of kaolinite, which acts as a filler and can impart a high gloss to a paper surface (Beazley 1991). The strong peaks for Al and Si in the known glossy magazine paper and the weak peaks for Al and Si in the known matte paper further suggested that the Al and Si are present as clay. The strong peaks for Al and Si in the brown paper sample were likely due to the presence of clay and suggest that the image may have come from a glossy page in a magazine rather than a matte paper like newsprint. The absence of other elements that would suggest inorganic pigments makes the use of synthetic organic colorants in the printing inks most likely. Many synthetic organic dyes are fugitive and may fade or discolor with light exposure. The minimal fading of the inks observed on the paper elements suggested that the artwork had largely been kept in dark storage. Because these inks are likely to fade and discolor further, it was recommended that the artwork be exhibited using low light levels appropriate for paper objects rather than the relatively high light levels used to exhibit paintings. In order to further investigate the dyes used in the paper printing inks Raman, Py-GC/MS, and DTMS could be used to analyze the available brown paper sample. The identity of these dyes would allow for greater knowledge of colorant stability and their potential for future fading.

The brilliance of the colors still intact on much of the paper surface was dulled by a layer of dirt which was removed during treatment using non-latex cosmetic sponges and the kneaded Design 1224 eraser, avoiding the introduction of moisture to the paper. In small areas of paper loss and abrasion, a barrier layer of methyl cellulose was applied and then toned using water colors.
D. Dust and Mold

Comparison of the chromatograms for the mineral spirit-extracted surface dirt sample and the mineral spirit-extracted wooden swab stick sample suggested that the petroleum wax found in the surface dirt chromatogram was actually from the wooden swab stick and not from the artwork. Squalene and palmitoleic acid are secreted from human skin tissue (Nikkari 1974; Kotani 2002). The presence of these compounds in the surface dirt chromatogram was likely due to the touching and handling of the artwork.

The presence of mold on the orange paint further supported the theory that the painting had encountered extended exposure to moisture, and the low relative humidity storage conditions recommended to mitigate the deterioration of the emerald green paint would also help prevent a recurrence of mold growth on the orange paint. Once the presence of mold was confirmed, the dark mold stains in the orange paint were reduced using a solution of 0.5% citrate, pH 6 with 1% (w/w) lysing enzymes dissolved into the solution. The enzymes break up the cell walls of the mold making it possible to remove the mold remnants with a damp swab. Because of the sensitivity of the orange paint, an application of cylcomethacone (a slow evaporating non-polar solvent) was first applied to an area of orange paint, and then the aqueous enzyme solution was applied in areas of mold using tiny cotton swabs. The cyclomethacone acted as a protective layer on the paint, repelling the water, but still allowing the enzyme to break up the mold.
The selective growth of the mold, only on the orange paint, was not fully explained by the results of this study. However, mold growth on the deteriorating emerald green paint was likely prevented due to the arsenic in emerald green, which is a natural fungicide, and the hydrophobic nature of Rhodamine dyes likely made the pink paint and unattractive site for mold growth. Further chromatographic analysis of the orange paint could yield more information about other components that may have contributed to the selective mold growth, especially considering the possible presence of water-sensitive stearate soaps.
V. CONCLUSIONS

Before treatment of artist Marion Greenstone’s Spoonk (1964), a Pop Art painted collage now owned by the Zimmerli Museum, technical analysis was conducted in order to better understand the condition of the various artwork components. Many colorants, binders, and fillers in the paints and paper elements were identified and found to be consistent with the date of creation. Most notable of the technical results was the probable presence of emerald green and cadmium yellow in the deteriorated green paint. These two pigments likely reacted to form black copper sulfides, causing the discoloration and flaking of these paint layers. Unfortunately, this deterioration process is likely to continue. The presence of mold on the artwork and the corrosion of metal attachments suggested that the artwork has suffered from exposure to moisture. The likely presence of synthetic organic dyes printed on the paper collage elements suggested that some of these colorants are probably prone to fading and discoloring upon light exposure. However, the minimal fading of the colorants that has been observed on the paper collage elements suggests that the artwork has thus far been protected from excessive light exposure. This information aided in the treatment of Spoonk and in the formulation of storage and exhibition guidelines for the artwork. This research will also contribute to the present information on Greenstone’s materials and working methods as well as that of her contemporaries.

VI. ACKNOWLEDGEMENTS

I would like to thank the Scientific Research and Analysis Laboratory at the Winterthur Museum including my project supervisor Dr. Joseph Weber, Dr. Jennifer Mass, Dr. Chris Petersen, Catherine Matsen, Melanie Gifford, and Chris Cole for all their assistance and advice with technical analysis and the interpretation of results. I would also like to thank Dr. Joyce Hill Stoner, Richard Wolbers, Mary McGinn, and Joan Irving for their guidance in treatment decisions and implementation, and thanks to the Zimmerli Art Museum Registrars Leslie Kriff and Margaret Molnar and Curator Jeff Wechsler for allowing me to conduct this study on an artwork from the Zimmerli collection. Others who encouraged and aided me along the way include Brian Baade, Jim Schneck, Debbie Hess Norris, Jae Gutierrez, Bruno Pouliot, and my classmates of WUDPAC 2010.

VII. REFERENCES

Archives of American Art. 2008. Marion Greenstone. Unpublished personal archives of Marion Greenstone. Smithsonian Archives of American Art, Washington D.C.

Beazley, K. 1991. Mineral fillers in paper. The paper conservator: journal of the Instittue of Paper Conservation (15): 17-27.
Boon, J.J., N. Wyplosz, F. Hoogland, M. Duursma, K. Keune, and T. Learner. 2004. Molecular Characterization and Mapping of Twentieth-Century Synthetic Organic Pigments and Additives in Paints. Proceedings of the IIC Biennial Congress Modern Art, New Museums. Bilbao, Spain. The International Institute for Conservation. 219.
Burnstock, A. et al. 2007. An Investigation of Water-Sensitive Oil Paints in Twentieth-Century Paintings. Modern Paints Uncovered. eds. Learner, T. et al. Los Angeles: Getty Conservation Institute. 177-188.
Burnstock, A. and A. Langley. 1999. The analysis of layered paint samples from modern paintings using FTIR microscopy. ICOM-CC Committee for Conservation 12^th triennial meeting. Lyon, France. London: James & James. 234-241.
Centeno, S.A. et al. 2006. Raman study of synthetic organic pigments and dyes in early lithographic inks (1890-1920). Journal of Raman Spectroscopy 37: 1111-1118.
Crook, J. and T. Learner. 2000. The Impact of Modern Paints. London: Tate Gallery Publishing Ltd.
Eccher, D. 1005. Tom Wesselmann. Rome: Museo D’Arte Contemporania.
Fiedler, I. and M. Bayard. 1986. Cadmium yellows, oranges and reds. In Artists' pigments: a handbook of their history and characteristics, ed. R.L. Feller. London: National Gallery of Art. 65-108.
Fiedler, I. and M. Bayard. 1997. Emerald green and Scheele's green. In Artists' pigments: a handbook of their history and characteristics. ed. E.W. FitzHugh. London: National Gallery of Art. 219-271.
Gettens, R.J. and G.L. Stout. 1966. Painting Materials: A short encylcopaedia. New York City: Dover Publications, Inc.
Grow, S. 2008. Condition Report and Treatment Proposal for Still Life #12 by Tom Wesselmann. Unpublished typescript in the Lunder Conservation Center conservation files. Smithsonian American Art Museum, Washington D.C.
Kotani, A. and F. Kusu. 2002. HPLC with electrochemical detection for determining the distribution of free fatty acids in skin surface lipids from the human face and scalp. Archives of Dermatological Research 294: 172-177.
Kriff, L. 2008. Personal communication. E-mail message to author.
Lake, S., E. Ordonez and M. Schilling. 2004. A technical investigation of paints used by Jackson Pollock in his drip or poured paintings. In Modern Art, New Museums: Contributions to the Bilbao Congress, 13-17 September 2004. Roy, A. and P. Smith, eds. 137-141. London: International Institute for Conservation of Historic and Artistic Works.
Learner, T., 2004. Analysis of Modern Paints. Los Angeles, California: The Getty Conservation Institute.
Learner, T. 1996. The use of FTIR in the conservation of twentieth century paintings. Spectroscopy Europe 8(4): 14-19.
Lomax, S., and T. Learner. 2006. A review of the classes, structures, and methods of analysis of synthetic organic pigments. Journal of the American Institute for Conservation 45(2): 107-25.
Madoff, S.H., ed. 1997. Pop Art: A Critical History. Berkeley, California: University of California Press.
Mustalish, R.A. 2000. Iptical brighteners: history and technology. In Tradition and innovation: advances in conservation: contributions to the Melbourne Congress, 10-14 October 2000. ed. A. Roy and P. Smith, Editors. International Institute for Conservation of Historic and Artistic Works. 133-136.

Nikkari, T., P.H. (1974) Schreibman, and E.H. Ahrens, Jr. In vivo studies of sterol and squalene secretion by human skin. Journal of Lipid Research (15) 563-573.

Ropret, P., S.A. Centeno, and P. Bukovec. 2008. Raman identification of yellow synthetic organic pigments in modern and contemporary paintings: Reference spectra and case studies. Spectrochimica Acta Part A (69): 486-497.
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Streitel, S. 1995 Fluorescent pigments (daylight). Encyclopedia of Chemical Technology 15: 585-607.
Tsang, J.S. 2008. Technical Report MCI 6213 Still Life #12 by Tom Wesselmann Smithsonian American Art Museum. Unpublished typescript. Smithsonian Museum Conservation Institute.
Tsang, J.S., S. E. Pinchin, K. Almond, and C.S. Tumosa. 2004. Conservation of Murals in the Alameda Theatre: Reviving Former Cutting-Edge Fluorescent Paint and Black-Light Technology. In Proceedings of the IIC Biennial Congress Modern Art, New Museums. Bilbao, Spain: The International Institute for Conservation. 185-188.
Vandenabeele. P., L. Moens, H.G.M. Edwards, and R. Dams. 2000. Raman spectroscopic database of azo pigments and application to modern art studies. Journal of Raman Spectroscopy (31): 509-517.
Vandenabeele, P., B. Welhing, L. Moens, H. Edwards, M. De Reu, and G. Van Hooydonk. 2000. Analysis with micro-Raman spectroscopy of natural organic binding media and varnishes used in art. Analytica Chimica Acta (407): 261-574.
Vandenabeele, P., H.G.M. Edwards, and L. Moens. 2006. A Decade of Raman Spectroscopy in Art and Archaeology. Chemical Reviews (107) 3: 675-686.
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VIII. APPENDIX

Table 1. X-Ray Fluorescence Spectroscopy Results

Sample__Description__Results'>Sample	Description	Results * (relevant elements in bold)	Colorants Inferred
Orange 1	orange paint	Zn, Sr, Se, Cd, Ba	cadmium orange or cadmium red lithopone, barium sulfate, zinc white
Orange 2	orange paint	Fe, Zn, Sr, Se, Cd, Ba,	cadmium orange or cadmium red lithopone, barium sulfate, zinc white
Green 1	degraded green paint	Fe, Cu, Zn, As, Cd,	emerald green, cadmium yellow, zinc white
Green 2	degraded green paint	Ca? Fe, Cu, Zn, As, Cd,	emerald green, cadmium yellow, zinc white
Black 1	black paint	Ca. Mn, Fe, Cu, Zn, As, Sr, Ba	barium sulfate, emerald green, zinc white
Black 2	black paint	Ca, Ti, Mn, Fe, Zn	titanium white
Light Pink	light pink paint	Ca, Ti, Fe, Zn	titanium white, zinc white,
Dark Pink	dark pink paint	Ca, Ti, Fe, Zn	titanium white, zinc white
Lips 1	yellow print on paper over paint	Ca, Ti, Fe, Cu, Zn, As, Cd	titanium white, emerald green, cadmium yellow
Tail Lights 1	orange print on paper over paint	Ca, Ti, Cr? Fe, Zn, Br, Pb	titanium white, zinc white
Silver 1	metallic paint	K, Ca, Ti, Cr, Fe, Zn	zinc white, titanium white
Yellow 1	yellow paint	Fe, Cu, Zn, Cd	zinc white, cadmium yellow
Golf ball 1	black print on paper over ground	Ca, Fe, Ti, Cr, Zn	titanium white, zinc white
Dark Green 1	dark green paint	Ca, Ti? Fe, Cu, Zn, Cd?, Ba	barium sulfate, zinc white

*Molybdenum from the x-ray tube was found in all XRF spectra

Table 2. Cross-sectional Analysis Results

Sample	Layers	Description		Fluorescent Staining Results
Sample	Layers	Visible light	Ultraviolet light	Carbohydrates	Proteins	Lipids
S-O2	1. orange	orange	brown	?	negative	?
	2. ground	white	bright white/blue	positive	negative	positive
	3. canvas fibers	grey	bright white/blue	negative	positive	negative
S-G1	1. lt. green	lt. green	blue	?	?	?
S-G1	2. dk. Green	dk. green	blue/grey	?	?	?
C5-green	1. lt. green	lt. green	blue	?	negative	positive
C5-green	2. dk. Green	dk. green	blue/grey	?	negative	?
C2-pink	1. lt. pink	lt. pink	bright orange	negative	negative	?
	2. dk. Pink	dk. pink	bright orange	negative	negative	?
	3. ground	white	grey	?	negative	positive
	4. ground	transparent	white/blue	negative	negative	negative
C1-ground	1. ground	white	grey	positive	negative	positive
C1-ground	2. ground	transparent	white/blue	negative	?	negative
S-GR1	1. ground	white (pink contaminant on top left)	light grey (yellow at top left)	positive	negative	positive
	2. ground	transparent, brown	white/blue	negative	positive	negative
	3. canvas fibers	transparent, brown	white/blue	?	negative	negative
S-GR2	1. ground	white	light grey	positive	negative	positive
S-GR2	2. ground	grey, transparent	blue-white	negative	positive	negative
S-S1	1. metallic paint	shiny, warm hue	black flecks in blue medium	negative	negative	positive
	2. resin?	transparent brown	white/blue	negative	negative	negative
	3. lt. green	lt. green	dk. green	?	negative	negative
	4. d. green	dk. green	black	?	negative	negative
S-B1	1. black	black	black	?	negative	negative
	2. lt. green	Lt. green	light blue	negative	negative	negative
	3. dk. Green	dk. green	grey/blue	?	negative	negative
S-B2	1. black	black	black	negative	negative	?
	2. metallic paint	shiny, warm hue	black flecks in blue medium	negative	negative	positive
	3. ground	white	grey	positive	negative	positive
	4. ground	transparent	white	negative	?	negative
S-DG1	1. dk. green	dk. green with red pigments	black	negative	negative	negative
	2. metallic paint	shiny, warm hue	black flecks in blue medium (possible layer separation?)	?	?	positive
	3. white	white with colored pigments	blue with dark pigments	positive	?	positive

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